Evolution of compound eye morphology underlies differences in vision between closely related Drosophila species.

Background: Insects have evolved complex visual systems and display an astonishing range of adaptations for diverse ecological niches. Species of Drosophila melanogaster subgroup exhibit extensive intra- and interspecific differences in compound eye size. These differences provide an excellent opportunity to better understand variation in insect eye structure and the impact on vision.

Proprioception gates visual object fixation in flying flies.

Visual object tracking in animals as diverse as felines, frogs, and fish supports behaviors including predation, predator avoidance, and landscape navigation. Decades of experimental results show that a rigidly body-fixed tethered fly in a "virtual reality" visual flight simulator steers to follow the motion of a vertical bar, thereby "fixating" it on visual midline. This behavior likely reflects a desire to seek natural features such as plant stalks and has inspired algorithms for visual object tracking predicated on robust responses to bar velocity, particularly near visual midline.

Measuring compound eye optics with microscope and microCT images.

With a great variety of shapes and sizes, compound eye morphologies give insight into visual ecology, development, and evolution, and inspire novel engineering. In contrast to our own camera-type eyes, compound eyes reveal their resolution, sensitivity, and field of view externally, provided they have spherical curvature and orthogonal ommatidia. Non-spherical compound eyes with skewed ommatidia require measuring internal structures, such as with MicroCT (µCT).

Acuity and summation strategies differ in vinegar and desert fruit flies.

An animal's vision depends on terrain features that limit the amount and distribution of available light. Approximately 10,000 years ago, vinegar flies () transitioned from a single plant specialist into a cosmopolitan generalist. Much earlier, desert flies () colonized the New World, specializing on rotting cactuses in southwest North America.

Prenatal incubation temperature affects neonatal precocial birds' locomotor behavior.

Temperature during the prenatal period is an important factor for developing embryos. Extensive human and animal research indicate embryos are sensitive to small fluctuations in temperature which has profound effects on phenotype development. Much of this research has focused on survivability, morphology, and incubation duration, but comparatively less in known about how prenatal temperature influences the development of motor coordination.

Small fruit flies sacrifice temporal acuity to maintain contrast sensitivity.

Holometabolous insects, like fruit flies, grow primarily during larval development. Scarce larval feeding is common in nature and generates smaller adults. Despite the importance of vision to flies, eye size scales proportionately with body size, and smaller eyes confer poorer vision due to smaller optics.